Multiplexed evaluation of capture agent binding kinetics using arrays of silicon photonic microring resonators

High affinity capture agents recognizing biomolecular targets are essential in the performance of many proteomic detection methods. Herein, we report the application of a label-free silicon photonic biomolecular analysis platform for simultaneously determining kinetic association and dissociation constants for two representative protein capture agents: a thrombin-binding DNA aptamer and an anti-thrombin monoclonal antibody. The scalability and inherent multiplexing capability of the technology make it an attractive platform for simultaneously evaluating the binding characteristics of multiple capture agents recognizing the same target antigen, and thus a tool complementary to emerging high-throughput capture agent generation strategies.     

A self-assembled fusion protein-based surface plasmon resonance biosensor for rapid diagnosis of severe acute respiratory syndrome

A surface plasmon resonance (SPR)-based biosensor was developed for simple diagnosis of severe acute respiratory syndrome (SARS) using a protein created by genetically fusing gold binding polypeptides (GBPs) to a SARS coronaviral surface antigen (SCVme). The GBP domain of the fusion protein serves as an anchoring component onto the gold surface, exploiting the gold binding affinity of the domain, whereas the SCVme domain is a recognition element for anti-SCVme antibody, the target analyte in this study. SPR analysis indicated the fusion protein simply and strongly self-immobilized onto the gold surface, through GBP, without surface chemical modification, offering a stable and specific sensing platform for anti-SCVme detection. AFM and SPR imaging analyses demonstrated that anti-SCVme specifically bound to the fusion protein immobilized onto the gold-micropatterned chip, implying that appropriate orientation of bound fusion protein by GBP resulted in optimal exposure of the SCVme domain to the assay solution, resulting in efficient capture of anti-SCVme antibody. The best packing density of the fusion protein onto the SPR chip was achieved at the concentration of 10 μg mL⁻¹; this density showed the highest detection response (906 RU) for anti-SCVme. The fusion protein-coated SPR chip at the best packing density had a lower limit of detection of 200 ng mL⁻¹ anti-SCVme within 10 min and also allowed selective detection of anti-SCVme with significantly low responses for non-specific mouse IgG at all tested concentrations. The fusion protein provides a simple and effective method for construction of SPR sensing platforms permitting sensitive and selective detection of anti-SCVme antibody.     

Carboxyl-terminated dendrimer-coated bioactive interface for protein microarray: high-sensitivity detection of antigen in complex biological samples

Protein microarrays are promising tools that can potentially enable high throughput proteomic screening in areas such as disease diagnosis and drug discovery. A critical aspect in the development of protein microarrays is the optimization of the array's surface chemistry to achieve the high sensitivity required for detection of proteins in cell lysate and other complex biological mixtures. In the present study, a high-density antibody array with minimal nonspecific cellular protein adsorption was prepared using a glass surface coated with a poly(propyleneimine) dendrimer terminated with carboxyl group (PAMAM-COOH). The carboxyl-terminated dendrimer-modified surface has almost similar nonspecific cellular protein adsorption when compared to an inert PEG-modified surface. In addition, the multiple functional sites available for reaction on the dendrimer surface facilitated high-density immobilization of antibodies and efficient capture of bioanalytes. Various molecules were tested for their ability to block or deactivate the reactive carboxyl surface after antibody immobilization to further reduce the nonspecific binding. A short oligoethylene glycol (NH2-d4-PEG-COOH), was found to significantly improve the signal-to-noise ratio of the assay, resulting in higher sensitivity. The properties and functional qualities of the various surfaces were characterized by contact angle and AFM measurements. Nonspecific protein adsorption and protein immobilization as a function of dendrimer generations and sensitivity of antigen capturing from a buffer (1 pM) as well as from the complex cell lysate (10 pM) system were examined. Our detailed experimental studies demonstrated a facile method of preparing surfaces with high protein loading and low nonspecific protein binding for the development of high sensitivity protein microarrays.     

Aptamer-containing surfaces for selective capture of CD4 expressing cells

Aptamers have recently emerged as an excellent alternative to antibodies because of their inherent stability and ease of modification. In this paper, we describe the development of an aptamer-based surface for capture of cells expressing CD4 antigen. The glass or silicon surfaces were modified with amine-terminated silanes and then modified with thiolated RNA aptamer against CD4. Modification of the surface was first characterized by ellipsometry to demonstrate assembly of biointerface components and to show specific capture of recombinant CD4 protein. Subsequently, surfaces were challenged with model lymphocytes (cell lines) that were either positive or negative for CD4 antigen. Our experiments show that aptamer-functionalized surfaces have similar capture efficiency to substrates containing anti-CD4 antibody. To mimick capture of specific T-cells from a complex cell mixture, aptamer-modified surfaces were exposed to binary mixtures containing Molt-3 cells (CD4+) spiked into Daudi B cells (CD4-). 94% purity of CD4 cells was observed on aptamer-containing surfaces from an initial fraction of 15% of CD4. Given the importance of CD4 cell enumeration in HIV/AIDS diagnosis and monitoring, aptamer-based devices may offer an opportunity for novel cell detection strategies and may yield more robust and less expensive blood analysis devices in the future.     

SERS as tool for the analysis of DNA-chips in a microfluidic platform

A sequence-specific detection method of DNA is presented combining a solid chip surface for immobilisation of capture DNAs with a microfluidic platform and a readout of the chip based on SERS. The solid chip surface is used for immobilisation of different capture DNAs, where target strands can be hybridised and unbound surfactants can be washed away. For the detection via SERS, short-labelled oligonucleotides are hybridised to the target strands. This technique is combined with a microfluidic platform that enables a fast and automated preparation process. By applying a chip format, the problems of sequence-specific DNA detection in solution phase by means of SERS can be overcome. With this setup, we are able to distinguish between different complementary and non-complementary target sequences in one sample solution.     

Development of a fully integrated microfluidic system for sensing infectious viral disease

An active micromixer system utilizing the magnetic force was developed and examined for its ability to facilitate the mixing of more than two fluid flows. The mixing performance of the active micromixer was evaluated in aqueous-aqueous systems including dyes for visual observation. A complete analytical microfluidic system was developed by integrating various functional modules into a single chip, thus allowing cell lysis, sample preparation, purification of intracellular molecules, and subsequent analysis. Upon loading the cell samples and lysis solution into the mixing chamber, the integrated microfluidic device allows efficient cell disruption by rotation of a micromagnetic disk and control of mixing time using the Teflon-coated hydrophobic film as a microvalve. This inflow is followed by separating the cell debris and contaminated proteins from the cell lysate sample using the acrylamide (AAm)-functionalized SPE. The inflow of partially purified cell lysate sample containing the gold binding polypeptide (GBP)-fusion protein was bound onto the gold micropatterns by means of its metal binding affinity. The GBP-fusion method allows immobilization of proteins in bioactive forms onto the gold surface without surface modification suitable for studying antigen-antibody interaction. It was used for the detection of severe acute respiratory syndrome (SARS), an infectious viral disease, as an example case.     

Carbohydrate monolayer strategy for electrochemical assay of cell surface carbohydrate

The study of glycobiology has been seriously hampered due to lack of an ideal assay tool. This work proposes a robust carbohydrate monolayer platform to solve the problems of active site inaccessibility and lectin denaturation associated with protein arrays reported for detection of cell surface carbohydrates and develops a convenient method for monitoring cell surface carbohydrate sites of interest, with high sensitivity, acceptable rapidity, low cost, and excellent extensibility. It utilizes the competitive binding of solid-surface-confined and cell-surface-residing carbohydrates to quantum dot labeled carbohydrate recognition protein and subsequent voltammetric quantification of the metal signature. The mannan monolayer strategy exhibited sensitive response to K562 cells and possessed potential specificity due to the specific interaction between lectin and corresponding carbohydrate. By comparing the competitive binding of K562 cells with mannan in solutions, the average Con A binding capacity of a single K562 cell could be estimated to correspond to 6.9 pg or 2.3 x 10(10) mannose moieties. This strategy integrates the advantages of surface assembly, nanotechnology, bioconjugate techniques, and electrochemical detection and can be expanded for profiling cell surface carbohydrates and high-throughput multiple detection by simultaneously using more pairs of lectin and carbohydrate owing to the multiple coding capability of QDs, which provides an important protocol for the quantitative evaluation of cell surface carbohydrate sites.     

Optimization of protein sample preparation for two-dimensional electrophoresis

Optimized 2DE sample preparation protocols that maximize total protein recovery are fundamental to improving proteome capture and increasing the utility of 2DE, which is in part limited by inadequate recovery of proteins with diverse physicochemical properties. Maintaining protein solubility is an important factor for protein recovery, but the multitude of solubility-enhancing agents and the relatively low-throughput nature of 2DE limit the systematic study of sample preparation. In this work, design of experiment (DOE) approaches are used to optimize protein recovery by altering the levels of four solubility-enhancing agents (urea, DTT, CHAPS, and SDS) in the initial suspension solution. Protein recovery is quantified by a total protein concentration assay, which is demonstrated to be representative of SDS-PAGE and 2DE recovery. DOE methodologies are presented as relatively high-throughput procedures for optimizing 2DE sample preparation parameters for a variety of sample types. Optimal suspension solution compositions are shown to vary across a model protein solution (no urea or DTT), Chinese hamster ovary (CHO) cell lysate (8 M urea, ≥2% CHAPS, ≥32.5 mM DTT), and Escherichia coli cell lysate (8 M urea, 4% CHAPS, 65 mM DTT), with optimized conditions increasing 2DE protein recovery at least 50% compared to suboptimal conditions.     

TMV microarrays: hybridization-based assembly of DNA-programmed viral nanotemplates

The intrinsic ability of biological molecules to self-organize into complex structures has the potential to revolutionize methods for the assembly of nanomaterials and devices. In this work, nucleic acid hybridization was used to simultaneously assemble different Tobacco mosaic virus (TMV) nanotemplates onto a glass substrate patterned with address specific capture DNAs. To accomplish this, TMV-based nanotemplates were programmed with linker DNAs containing sequence specific addresses and hybridized directly to the capture DNAs. This assembly process proved to be a reliable, selective, and controllable means to assemble multiple TMV nanotemplates.     

Quantum dots-based reverse phase protein microarray

CdSe nanocrystals, also called quantum dots (Qdots) are a novel class of fluorophores, which have a diameter of a few nanometers and possess high quantum yield, tunable emission wavelength and photostability. They are an attractive alternative to conventional fluorescent dyes. Quantum dots can be silanized to be soluble in aqueous solution under biological conditions, and thus be used in bio-detection. In this study, we established a novel Qdot-based technology platform that can perform accurate and reproducible quantification of protein concentration in a crude cell lysate background. Protein lysates have been spiked with a target protein, and a dilution series of the cell lysate with a dynamic range of three orders of magnitude has been used for this proof-of-concept study. The dilution series has been spotted in microarray format, and protein detection has been achieved with a sensitivity that is at least comparable to standard commercial assays, which are based on horseradish peroxidase (HRP)-catalyzed diaminobenzidine (DAB) chromogenesis. The data obtained through the Qdot method has shown a close linear correlation between relative fluorescence unit and relative protein concentration. The Qdot results are in almost complete agreement with data we obtained with the well-established HRP-DAB colorimetric array (R² = 0.986). This suggests that Qdots can be used for protein quantification in microarray format, using the platform presented here.     

Spatially addressable chemoselective C-terminal ligation of an intein fusion protein from a complex mixture to a hydrazine-terminated surface

Protein immobilization on surfaces is useful in many areas of research, including biological characterization, antibody purification, and clinical diagnostics. A critical limitation in the development of protein microarrays and heterogeneous protein-based assays is the enormous amount of work and associated costs in the purification of proteins prior to their immobilization onto a surface. Methods to address this problem would simplify the development of interfacial diagnostics that use a protein as the recognition element. Herein, we describe an approach for the facile, site-specific immobilization of proteins on a surface without any preprocessing or sample purification steps that ligates an intein fusion protein at its C-terminus by reaction with a hydrazine group presented by a surface. Furthermore, we demonstrate that this methodology can directly immobilize a protein directly from cell lysate onto a protein-resistant surface. This methodology is also compatible with soft lithography and inkjet printing so that one or more proteins can be patterned on a surface without the need for purification.     

Fully automated immunoassay for detection of prostate-specific antigen using nano-magnetic beads and micro-polystyrene bead composites, 'Beads on Beads'

Magnetic beads have served as a conventional bioassay platform in biotechnology. In this study, a fully automated immunoassay was performed using novel nano- and microbead-composites constructed by assembling nano-magnetic beads onto polystyrene microbeads, designated ‘Beads on Beads’. Nano-sized bacterial magnetic particles (BacMPs) displaying the immunoglobulin G (IgG)-binding domain of protein A (ZZ domain) were used for the construction of ‘Beads on Beads’ via the interaction of biotin-streptavidin. The efficient assembly of ‘Beads on Beads’ was performed by gradual addition of biotin-labeled BacMPs onto streptavidin-coated polystyrene microbeads. Approximately 2000 BacMPs were uniformly assembled on a single microbead without aggregation. The constructed ‘Beads on Beads’ were magnetized and separated from the suspension by using an automated magnetic separation system with a higher efficiency than BacMPs alone. Furthermore, fully automated detection of prostate-specific antigens was performed with the detection limit of 1.48 ng mL⁻¹. From this preliminary assay, it can be seen that ‘Beads on Beads’ could be a powerful tool in the development of high-throughput, fully automated multiplexed bioassays.     

Development of online high-/low-pH reversed-phase-reversed-phase two-dimensional liquid chromatography for shotgun proteomics: a reversed-phase-strong cation exchange-reversed-phase approach

Previously, we described an online high-/low-pH RP-RP LC system exhibiting high-throughput, automatability, and performance comparable with that of SCX-RP. Herein, we report a variant of the RP-RP platform, RP-SCX-RP, featuring an additional SCX trap column between the two LC dimensions. The SCX column in combination with the second-dimension RP can be used as an SCX-RP biphasic column for trapping peptides in the eluent from the first RP column. We evaluated the performance of the new platform through proteomic analysis of Arabidopsis thaliana chloroplast samples and mouse embryonic mouse fibroblast STO cell lysate at low-microgram levels. In general, RP-SCX-RP enhanced protein identification by allowing the detection of a larger number of hydrophilic peptides. Furthermore, the platform was useful for the quantitative analyses of crude chloroplast samples for iTRAQ applications at low-microgram levels. In addition, it allowed the online removal of sodium dodecyl sulfate and other chemicals used in excess in iTRAQ reactions, avoiding the need for time-consuming offline SCX clean-up prior to RP-RP separation. Relative to the RP-RP system, our newly developed RP-SCX-RP platform allowed the detection of a larger number of differentially expressed proteins in a crude iTRAQ-labeled chloroplast protein sample.     

Direct detection of native proteins in biological matrices using extractive electrospray ionization mass spectrometry

The high-throughput and sensitive characterization of native proteins in biological samples is of increasing interest in multiple disciplines. Extractive electrospray ionization (EESI) forms ions of native proteins including lysozyme, α-chymotrypsin, myoglobin, human serum albumin, RNAse A and blood hemoglobin in extremely complex biosamples or PBS buffer solutions by softly depositing charges on the protein molecules. This method produces no significant conformational changes of the proteins in the ion formation process, and features direct detection of trace proteins present in biological matrices. The detection limit of low pmol L(-1) for lysozyme in untreated biological liquids such as human urine and tears was demonstrated using EESI mass spectrometry (MS), showing an attractive MS platform for the direct analysis of native proteins in actual biological samples.     

A Mix‐and‐Read Fluorescence Strategy for the Switch‐On Probing of Kinase Activity Based on an Aptameric‐Peptide/Graphene‐Oxide Platform

Protein kinase plays a vital role in regulating signal‐transduction pathways and its simple and quick detection is highly desirable because traditional kinase assays typically rely on a time‐consuming kinase‐phosphorylation process (ca. 1 h). Herein, we report a new and rapid fluorescence‐based sensing platform for probing the activity of protein kinase that is based on the super‐quenching capacity of graphene oxide (GO) nanosheets and specific recognition of the aptameric peptide (FITC‐IP₂₀). On the GO/peptide platform, the fluorescence quenching of FITC‐IP₂₀ that is adsorbed onto GO can be restored by selective binding of active protein kinase to the aptameric peptide, thereby resulting in the fast switch‐on detection of kinase activity (ca. 15 min). The feasibility of this method has been demonstrated by the sensitive measurement of the activity of cAMP‐dependent protein kinase (PKA), with a detection limit of 0.053 mU μL^?1. This assay technique was also successfully applied to the detection of kinase activation in cell lysate.     

Catch,Modify and Analyze: Methods of Chemoselective Modification of Cysteine-Containing Peptides

One effective solution in the analysis of complex mixtures, including protein or cell hydrolysates, is based on chemoselective derivatization of a selected group of compounds by using selective tags to facilitate detection. Another method is based on the capture of the desired compounds by properly designed solid supports, resulting in sample enrichment. Cysteine is one of the rarest amino acids, but at least one cysteine residue is present in more than 91% of human proteins, which clearly confirms its important role in biological systems. Some cysteine-containing peptides may serve as significant molecular biomarkers, which may emerge as key indices in the management of patients with particular diseases. In the current review, we describe recent advances in the development of cysteine-containing peptide modification techniques based on solution and solid phase derivatization and enrichment strategies.     

Time-resolved fluorescence aptamer-based sandwich assay for thrombin detection

In the present study, the authors report a novel sensitive method for the detection of thrombin using time-resolved fluorescence sensing platform based on two different thrombin aptamers. The thrombin 15-mer aptamer as a capture probe was covalently attached to the surface of glass slide, and the thrombin 29-mer aptamer was fluorescently labeled as a detection probe. A bifunctional europium complex was used as the fluorescent label. The introduction of thrombin triggers the two different thrombin aptamers and thrombin to form a sandwich structure. The fluorescence intensity is proportional to the thrombin concentration. The present sensing system could provide both a wide linear dynamic range and a low detection limit. The proposed sensing system also presented satisfactory specificity and selectivity. Results showed that thrombin was retained at the aptamer-modified glass surface while nonspecific proteins were removed by rinsing with buffer solution. This approach successfully showed the suitability of aptamers as low molecular weight receptors on glass slides for sensitive and specific protein detection.     

Digital droplet immunoassay based on a microfluidic chip with magnetic beads for the detection of prostate-specific antigen

Sensitive biomarker detection techniques are beneficial for both disease diagnosis and postoperative examinations. In this study, we report an integrated microfluidic chip designed for the immunodetection of prostate-specific antigens (PSAs). The microfluidic chip is based on the three-dimensional structure of quartz capillaries. The outlet channel extends to 1.8 cm, effectively facilitating the generation of uniform droplets ranging in size from 3 to 50 μm. Furthermore, we successfully immobilized the captured antibodies onto the surface of magnetic beads using an activator, and we constructed an immunosandwich complex by employing biotinylated antibodies. A key feature of this microfluidic chip is its integration of microfluidic droplet technology advantages, such as high-throughput parallelism, enzymatic signal amplification, and small droplet size. This integration results in an exceptionally sensitive PSA detection capability, with the detection limit reduced to 7.00 ± 0.62 pg/mL.     

A simple kinetic model of antigen-antibody reactions in particle-enhanced light scattering immunoassays

Polymer colloids coated by antibodies are used in diagnostic tests for the detection of antigens in biological fluids. We present in this paper a simple kinetic model for the optical monitoring of the formation of specific complexes between antigen and antibody with amplification by latex beads. The antibodies are physical or chemically adsorbed onto sulphonate polystyrene or chloromethylstyrene particles respectively. This is a very simple model combining the La Mer idea of optimum surface coverage with Langmuir adsorption of antigen molecules. The kinetic model explains reasonably well the optical response of immunolatex prepared by both methods of immobilization of antibodies on polymer carriers. According to the results obtained with this model the percentage of active IgG on latex particles is extremely low, with a maximum of a 5%.     

Detection of tetracysteine-tagged proteins using a biarsenical fluorescein derivative through dry microplate array gel electrophoresis

The design of an extended-run 96-well sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) system and the development of protein detection technology based upon fluorescein derivatives that bind to peptide epitope tags, allows the creation of a truly high-throughput analysis of protein expression, where less than 20 min are needed to separate proteins and analyze results. We demonstrate the overall capabilities of such a method combination in a complex cell lysate background, while comparing the specific results obtained using a biarsenical fluorescein-derivative and tetracysteine epitope-tagged proteins with total protein staining using a fluorescent gel stain and with Western blotting where an anti-oligohistidine (His) tag antibody has been employed. When applied on purified target proteins without extraneous protein background, the demonstrated sensitivity of the assay on the extended-run 96-array precast SDS-PAGE system allows detection of quantities of tagged protein as low as 1 pmol per band.